Norimasa Okamoto
BTstack Bluetooth stack
USBホストライブラリを変更しました。
- Bluetoothマウス(VGP-BMS33)での動作を確認しました。mouse_demo.cpp
BTstack/sdp_util.c
- Committer:
- va009039
- Date:
- 2013-03-22
- Revision:
- 2:871b41f4789e
- Parent:
- 0:1ed23ab1345f
File content as of revision 2:871b41f4789e:
/*
* Copyright (C) 2009-2012 by Matthias Ringwald
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the copyright holders nor the names of
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
* 4. Any redistribution, use, or modification is done solely for
* personal benefit and not for any commercial purpose or for
* monetary gain.
*
* THIS SOFTWARE IS PROVIDED BY MATTHIAS RINGWALD AND CONTRIBUTORS
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL MATTHIAS
* RINGWALD OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF
* THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* Please inquire about commercial licensing options at btstack@ringwald.ch
*
*/
/*
* sdp_util.c
*/
#include <btstack/sdp_util.h>
#include <btstack/utils.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdint.h>
#include <inttypes.h> // PRIx32
// workaround for missing PRIx32 on mspgcc (16-bit MCU)
#ifndef PRIx32
#warning Using own: #define PRIx32 "lx"
#define PRIx32 "lx"
#endif
// date element type names
const char * const type_names[] = { "NIL", "UINT", "INT", "UUID", "STRING", "BOOL", "DES", "DEA", "URL"};
// Bluetooth Base UUID: 00000000-0000-1000-8000- 00805F9B34FB
const uint8_t sdp_bluetooth_base_uuid[] = { 0x00, 0x00, 0x00, 0x00, /* - */ 0x00, 0x00, /* - */ 0x10, 0x00, /* - */
0x80, 0x00, /* - */ 0x00, 0x80, 0x5F, 0x9B, 0x34, 0xFB };
void sdp_normalize_uuid(uint8_t *uuid, uint32_t shortUUID){
memcpy(uuid, sdp_bluetooth_base_uuid, 16);
net_store_32(uuid, 0, shortUUID);
}
// MARK: DataElement getter
de_size_t de_get_size_type(uint8_t *header){
return (de_size_t) (header[0] & 7);
}
de_type_t de_get_element_type(uint8_t *header){
return (de_type_t) (header[0] >> 3);
}
int de_get_header_size(uint8_t * header){
de_size_t de_size = de_get_size_type(header);
if (de_size <= DE_SIZE_128) {
return 1;
}
return 1 + (1 << (de_size-DE_SIZE_VAR_8));
}
int de_get_data_size(uint8_t * header){
uint32_t result = 0;
de_type_t de_type = de_get_element_type(header);
de_size_t de_size = de_get_size_type(header);
switch (de_size){
case DE_SIZE_VAR_8:
result = header[1];
break;
case DE_SIZE_VAR_16:
result = READ_NET_16(header,1);
break;
case DE_SIZE_VAR_32:
result = READ_NET_32(header,1);
break;
default:
// case DE_SIZE_8:
// case DE_SIZE_16:
// case DE_SIZE_32:
// case DE_SIZE_64:
// case DE_SIZE_128:
if (de_type == DE_NIL) return 0;
return 1 << de_size;
}
return result;
}
int de_get_len(uint8_t *header){
return de_get_header_size(header) + de_get_data_size(header);
}
// @returns: element is valid UUID
int de_get_normalized_uuid(uint8_t *uuid128, uint8_t *element){
de_type_t uuidType = de_get_element_type(element);
de_size_t uuidSize = de_get_size_type(element);
if (uuidType != DE_UUID) return 0;
uint32_t shortUUID;
switch (uuidSize){
case DE_SIZE_16:
shortUUID = READ_NET_16(element, 1);
break;
case DE_SIZE_32:
shortUUID = READ_NET_32(element, 1);
break;
case DE_SIZE_128:
memcpy(uuid128, element+1, 16);
return 1;
default:
return 0;
}
sdp_normalize_uuid(uuid128, shortUUID);
return 1;
}
// functions to create record
static void de_store_descriptor(uint8_t * header, de_type_t type, de_size_t size){
header[0] = (type << 3) | size;
}
void de_store_descriptor_with_len(uint8_t * header, de_type_t type, de_size_t size, uint32_t len){
header[0] = (type << 3) | size;
switch (size){
case DE_SIZE_VAR_8:
header[1] = len;
break;
case DE_SIZE_VAR_16:
net_store_16(header, 1, len);
break;
case DE_SIZE_VAR_32:
net_store_32(header, 1, len);
break;
default:
break;
}
}
// MARK: DataElement creation
/* starts a new sequence in empty buffer - first call */
void de_create_sequence(uint8_t *header){
de_store_descriptor_with_len( header, DE_DES, DE_SIZE_VAR_16, 0); // DES, 2 Byte Length
};
/* starts a sub-sequence, @returns handle for sub-sequence */
uint8_t * de_push_sequence(uint8_t *header){
int element_len = de_get_len(header);
de_store_descriptor_with_len(header+element_len, DE_DES, DE_SIZE_VAR_16, 0); // DES, 2 Byte Length
return header + element_len;
}
/* closes the current sequence and updates the parent sequence */
void de_pop_sequence(uint8_t * parent, uint8_t * child){
int child_len = de_get_len(child);
int data_size_parent = READ_NET_16(parent,1);
net_store_16(parent, 1, data_size_parent + child_len);
}
/* adds a single number value and 16+32 bit UUID to the sequence */
void de_add_number(uint8_t *seq, de_type_t type, de_size_t size, uint32_t value){
int data_size = READ_NET_16(seq,1);
int element_size = 1; // e.g. for DE_TYPE_NIL
de_store_descriptor(seq+3+data_size, type, size);
switch (size){
case DE_SIZE_8:
if (type != DE_NIL){
seq[4+data_size] = value;
element_size = 2;
}
break;
case DE_SIZE_16:
net_store_16(seq, 4+data_size, value);
element_size = 3;
break;
case DE_SIZE_32:
net_store_32(seq, 4+data_size, value);
element_size = 5;
break;
default:
break;
}
net_store_16(seq, 1, data_size+element_size);
}
/* add a single block of data, e.g. as DE_STRING, DE_URL */
void de_add_data( uint8_t *seq, de_type_t type, uint16_t size, uint8_t *data){
int data_size = READ_NET_16(seq,1);
if (size > 0xff) {
// use 16-bit lengh information (3 byte header)
de_store_descriptor_with_len(seq+3+data_size, type, DE_SIZE_VAR_16, size);
data_size += 3;
} else {
// use 8-bit lengh information (2 byte header)
de_store_descriptor_with_len(seq+3+data_size, type, DE_SIZE_VAR_8, size);
data_size += 2;
}
memcpy( seq + 3 + data_size, data, size);
data_size += size;
net_store_16(seq, 1, data_size);
}
void de_add_uuid128(uint8_t * seq, uint8_t * uuid){
int data_size = READ_NET_16(seq,1);
de_store_descriptor(seq+3+data_size, DE_UUID, DE_SIZE_128);
memcpy( seq + 4 + data_size, uuid, 16);
net_store_16(seq, 1, data_size+1+16);
}
void sdp_add_attribute(uint8_t *seq, uint16_t attributeID, uint8_t attributeValue){
}
// MARK: DataElementSequence traversal
typedef int (*de_traversal_callback_t)(uint8_t * element, de_type_t type, de_size_t size, void *context);
static void de_traverse_sequence(uint8_t * element, de_traversal_callback_t handler, void *context){
de_type_t type = de_get_element_type(element);
if (type != DE_DES) return;
int pos = de_get_header_size(element);
int end_pos = de_get_len(element);
while (pos < end_pos){
de_type_t elemType = de_get_element_type(element + pos);
de_size_t elemSize = de_get_size_type(element + pos);
uint8_t done = (*handler)(element + pos, elemType, elemSize, context);
if (done) break;
pos += de_get_len(element + pos);
}
}
// MARK: AttributeList traversal
typedef int (*sdp_attribute_list_traversal_callback_t)(uint16_t attributeID, uint8_t * attributeValue, de_type_t type, de_size_t size, void *context);
static void sdp_attribute_list_traverse_sequence(uint8_t * element, sdp_attribute_list_traversal_callback_t handler, void *context){
de_type_t type = de_get_element_type(element);
if (type != DE_DES) return;
int pos = de_get_header_size(element);
int end_pos = de_get_len(element);
while (pos < end_pos){
de_type_t idType = de_get_element_type(element + pos);
de_size_t idSize = de_get_size_type(element + pos);
if (idType != DE_UINT || idSize != DE_SIZE_16) break; // wrong type
uint16_t attribute_id = READ_NET_16(element, pos + 1);
pos += 3;
if (pos >= end_pos) break; // array out of bounds
de_type_t valueType = de_get_element_type(element + pos);
de_size_t valueSize = de_get_size_type(element + pos);
uint8_t done = (*handler)(attribute_id, element + pos, valueType, valueSize, context);
if (done) break;
pos += de_get_len(element + pos);
}
}
// MARK: AttributeID in AttributeIDList
// attribute ID in AttributeIDList
// context { result, attributeID }
struct sdp_context_attributeID_search {
int result;
uint16_t attributeID;
};
static int sdp_traversal_attributeID_search(uint8_t * element, de_type_t type, de_size_t size, void *my_context){
struct sdp_context_attributeID_search * context = (struct sdp_context_attributeID_search *) my_context;
if (type != DE_UINT) return 0;
switch (size) {
case DE_SIZE_16:
if (READ_NET_16(element, 1) == context->attributeID) {
context->result = 1;
return 1;
}
break;
case DE_SIZE_32:
if (READ_NET_16(element, 1) <= context->attributeID
&& context->attributeID <= READ_NET_16(element, 3)) {
context->result = 1;
return 1;
}
break;
default:
break;
}
return 0;
}
int sdp_attribute_list_constains_id(uint8_t *attributeIDList, uint16_t attributeID){
struct sdp_context_attributeID_search attributeID_search;
attributeID_search.result = 0;
attributeID_search.attributeID = attributeID;
de_traverse_sequence(attributeIDList, sdp_traversal_attributeID_search, &attributeID_search);
return attributeID_search.result;
}
// MARK: Append Attributes for AttributeIDList
// pre: buffer contains DES with 2 byte length field
struct sdp_context_append_attributes {
uint8_t * buffer;
uint16_t startOffset; // offset of when to start copying
uint16_t maxBytes;
uint16_t usedBytes;
uint8_t *attributeIDList;
};
static int sdp_traversal_append_attributes(uint16_t attributeID, uint8_t * attributeValue, de_type_t type, de_size_t size, void *my_context){
struct sdp_context_append_attributes * context = (struct sdp_context_append_attributes *) my_context;
if (sdp_attribute_list_constains_id(context->attributeIDList, attributeID)) {
// DES_HEADER(3) + DES_DATA + (UINT16(3) + attribute)
uint16_t data_size = READ_NET_16(context->buffer, 1);
int attribute_len = de_get_len(attributeValue);
if (3 + data_size + (3 + attribute_len) <= context->maxBytes) {
// copy Attribute
de_add_number(context->buffer, DE_UINT, DE_SIZE_16, attributeID);
data_size += 3; // 3 bytes
memcpy(context->buffer + 3 + data_size, attributeValue, attribute_len);
net_store_16(context->buffer,1,data_size+attribute_len);
} else {
// not enought space left -> continue with previous element
return 1;
}
}
return 0;
}
// maxBytes: maximal size of data element sequence
uint16_t sdp_append_attributes_in_attributeIDList(uint8_t *record, uint8_t *attributeIDList, uint16_t startOffset, uint16_t maxBytes, uint8_t *buffer){
struct sdp_context_append_attributes context;
context.buffer = buffer;
context.maxBytes = maxBytes;
context.usedBytes = 0;
context.startOffset = startOffset;
context.attributeIDList = attributeIDList;
sdp_attribute_list_traverse_sequence(record, sdp_traversal_append_attributes, &context);
return context.usedBytes;
}
// MARK: Filter attributes that match attribute list from startOffset and a max nr bytes
struct sdp_context_filter_attributes {
uint8_t * buffer;
uint16_t startOffset; // offset of when to start copying
uint16_t maxBytes;
uint16_t usedBytes;
uint8_t *attributeIDList;
int complete;
};
// copy data with given start offset and max bytes, returns OK if all data has been copied
static int spd_append_range(struct sdp_context_filter_attributes* context, uint16_t len, uint8_t *data){
int ok = 1;
uint16_t remainder_len = len - context->startOffset;
if (context->maxBytes < remainder_len){
remainder_len = context->maxBytes;
ok = 0;
}
memcpy(context->buffer, &data[context->startOffset], remainder_len);
context->usedBytes += remainder_len;
context->buffer += remainder_len;
context->maxBytes -= remainder_len;
context->startOffset = 0;
return ok;
}
static int sdp_traversal_filter_attributes(uint16_t attributeID, uint8_t * attributeValue, de_type_t type, de_size_t size, void *my_context){
struct sdp_context_filter_attributes * context = (struct sdp_context_filter_attributes *) my_context;
if (!sdp_attribute_list_constains_id(context->attributeIDList, attributeID)) return 0;
// { Attribute ID (Descriptor, big endian 16-bit ID), AttributeValue (data)}
// handle Attribute ID
if (context->startOffset >= 3){
context->startOffset -= 3;
} else {
uint8_t idBuffer[3];
de_store_descriptor(idBuffer, DE_UINT, DE_SIZE_16);
net_store_16(idBuffer,1,attributeID);
int ok = spd_append_range(context, 3, idBuffer);
if (!ok) {
context->complete = 0;
return 1;
}
}
// handle Attribute Value
int attribute_len = de_get_len(attributeValue);
if (context->startOffset >= attribute_len) {
context->startOffset -= attribute_len;
return 0;
}
int ok = spd_append_range(context, attribute_len, attributeValue);
if (!ok) {
context->complete = 0;
return 1;
}
return 0;
}
int sdp_filter_attributes_in_attributeIDList(uint8_t *record, uint8_t *attributeIDList, uint16_t startOffset, uint16_t maxBytes, uint16_t *usedBytes, uint8_t *buffer){
struct sdp_context_filter_attributes context;
context.buffer = buffer;
context.maxBytes = maxBytes;
context.usedBytes = 0;
context.startOffset = startOffset;
context.attributeIDList = attributeIDList;
context.complete = 1;
sdp_attribute_list_traverse_sequence(record, sdp_traversal_filter_attributes, &context);
*usedBytes = context.usedBytes;
return context.complete;
}
// MARK: Get sum of attributes matching attribute list
struct sdp_context_get_filtered_size {
uint8_t *attributeIDList;
uint16_t size;
};
static int sdp_traversal_get_filtered_size(uint16_t attributeID, uint8_t * attributeValue, de_type_t type, de_size_t size, void *my_context){
struct sdp_context_get_filtered_size * context = (struct sdp_context_get_filtered_size *) my_context;
if (sdp_attribute_list_constains_id(context->attributeIDList, attributeID)) {
context->size += 3 + de_get_len(attributeValue);
}
return 0;
}
int spd_get_filtered_size(uint8_t *record, uint8_t *attributeIDList){
struct sdp_context_get_filtered_size context;
context.size = 0;
context.attributeIDList = attributeIDList;
sdp_attribute_list_traverse_sequence(record, sdp_traversal_get_filtered_size, &context);
return context.size;
}
// MARK: Get AttributeValue for AttributeID
// find attribute (ELEMENT) by ID
struct sdp_context_attribute_by_id {
uint16_t attributeID;
uint8_t * attributeValue;
};
static int sdp_traversal_attribute_by_id(uint16_t attributeID, uint8_t * attributeValue, de_type_t attributeType, de_size_t size, void *my_context){
struct sdp_context_attribute_by_id * context = (struct sdp_context_attribute_by_id *) my_context;
if (attributeID == context->attributeID) {
context->attributeValue = attributeValue;
return 1;
}
return 0;
}
uint8_t * sdp_get_attribute_value_for_attribute_id(uint8_t * record, uint16_t attributeID){
struct sdp_context_attribute_by_id context;
context.attributeValue = NULL;
context.attributeID = attributeID;
sdp_attribute_list_traverse_sequence(record, sdp_traversal_attribute_by_id, &context);
return context.attributeValue;
}
// MARK: Set AttributeValue for AttributeID
struct sdp_context_set_attribute_for_id {
uint16_t attributeID;
uint32_t attributeValue;
uint8_t attributeFound;
};
static int sdp_traversal_set_attribute_for_id(uint16_t attributeID, uint8_t * attributeValue, de_type_t attributeType, de_size_t size, void *my_context){
struct sdp_context_set_attribute_for_id * context = (struct sdp_context_set_attribute_for_id *) my_context;
if (attributeID == context->attributeID) {
context->attributeFound = 1;
switch (size){
case DE_SIZE_8:
if (attributeType != DE_NIL){
attributeValue[1] = context->attributeValue;
}
break;
case DE_SIZE_16:
net_store_16(attributeValue, 1, context->attributeValue);
break;
case DE_SIZE_32:
net_store_32(attributeValue, 1, context->attributeValue);
break;
// Might want to support STRINGS to, copy upto original length
default:
break;
}
return 1;
}
return 0;
}
uint8_t sdp_set_attribute_value_for_attribute_id(uint8_t * record, uint16_t attributeID, uint32_t value){
struct sdp_context_set_attribute_for_id context;
context.attributeID = attributeID;
context.attributeValue = value;
context.attributeFound = 0;
sdp_attribute_list_traverse_sequence(record, sdp_traversal_set_attribute_for_id, &context);
return context.attributeFound;
}
// MARK: ServiceRecord contains UUID
// service record contains UUID
// context { normalizedUUID }
struct sdp_context_contains_uuid128 {
uint8_t * uuid128;
int result;
};
int sdp_record_contains_UUID128(uint8_t *record, uint8_t *uuid128);
static int sdp_traversal_contains_UUID128(uint8_t * element, de_type_t type, de_size_t size, void *my_context){
struct sdp_context_contains_uuid128 * context = (struct sdp_context_contains_uuid128 *) my_context;
uint8_t normalizedUUID[16];
if (type == DE_UUID){
uint8_t uuidOK = de_get_normalized_uuid(normalizedUUID, element);
context->result = uuidOK && memcmp(context->uuid128, normalizedUUID, 16) == 0;
}
if (type == DE_DES){
context->result = sdp_record_contains_UUID128(element, context->uuid128);
}
return context->result;
}
int sdp_record_contains_UUID128(uint8_t *record, uint8_t *uuid128){
struct sdp_context_contains_uuid128 context;
context.uuid128 = uuid128;
context.result = 0;
de_traverse_sequence(record, sdp_traversal_contains_UUID128, &context);
return context.result;
}
// MARK: ServiceRecord matches SearchServicePattern
// if UUID in searchServicePattern is not found in record => false
// context { result, record }
struct sdp_context_match_pattern {
uint8_t * record;
int result;
};
int sdp_traversal_match_pattern(uint8_t * element, de_type_t attributeType, de_size_t size, void *my_context){
struct sdp_context_match_pattern * context = (struct sdp_context_match_pattern *) my_context;
uint8_t normalizedUUID[16];
uint8_t uuidOK = de_get_normalized_uuid(normalizedUUID, element);
if (!uuidOK || !sdp_record_contains_UUID128(context->record, normalizedUUID)){
context->result = 0;
return 1;
}
return 0;
}
int sdp_record_matches_service_search_pattern(uint8_t *record, uint8_t *serviceSearchPattern){
struct sdp_context_match_pattern context;
context.record = record;
context.result = 1;
de_traverse_sequence(serviceSearchPattern, sdp_traversal_match_pattern, &context);
return context.result;
}
// MARK: Dump DataElement
// context { indent }
static int de_traversal_dump_data(uint8_t * element, de_type_t de_type, de_size_t de_size, void *my_context){
int indent = *(int*) my_context;
int i;
for (i=0; i<indent;i++) printf(" ");
int pos = de_get_header_size(element);
int end_pos = de_get_len(element);
printf("type %5s (%u), element len %2u ", type_names[de_type], de_type, end_pos);
if (de_type == DE_DES) {
printf("\n");
indent++;
de_traverse_sequence(element, de_traversal_dump_data, (void *)&indent);
} else if (de_type == DE_UUID && de_size == DE_SIZE_128) {
printf(", value: ");
printUUID(element+1);
printf("\n");
} else if (de_type == DE_STRING) {
int len = 0;
switch (de_size){
case DE_SIZE_VAR_8:
len = element[1];
break;
case DE_SIZE_VAR_16:
len = READ_NET_16(element, 1);
break;
default:
break;
}
printf("len %u (0x%02x)\n", len, len);
hexdump(&element[pos], len);
} else {
uint32_t value = 0;
switch (de_size) {
case DE_SIZE_8:
if (de_type != DE_NIL){
value = element[pos];
}
break;
case DE_SIZE_16:
value = READ_NET_16(element,pos);
break;
case DE_SIZE_32:
value = READ_NET_32(element,pos);
break;
default:
break;
}
printf(", value: 0x%08" PRIx32 "\n", value);
}
return 0;
}
void de_dump_data_element(uint8_t * record){
int indent = 0;
// hack to get root DES, too.
de_type_t type = de_get_element_type(record);
de_size_t size = de_get_size_type(record);
de_traversal_dump_data(record, type, size, (void*) &indent);
}
void sdp_create_spp_service(uint8_t *service, int service_id, const char *name){
uint8_t* attribute;
de_create_sequence(service);
// 0x0000 "Service Record Handle"
de_add_number(service, DE_UINT, DE_SIZE_16, SDP_ServiceRecordHandle);
de_add_number(service, DE_UINT, DE_SIZE_32, 0x10001);
// 0x0001 "Service Class ID List"
de_add_number(service, DE_UINT, DE_SIZE_16, SDP_ServiceClassIDList);
attribute = de_push_sequence(service);
{
de_add_number(attribute, DE_UUID, DE_SIZE_16, 0x1101 );
}
de_pop_sequence(service, attribute);
// 0x0004 "Protocol Descriptor List"
de_add_number(service, DE_UINT, DE_SIZE_16, SDP_ProtocolDescriptorList);
attribute = de_push_sequence(service);
{
uint8_t* l2cpProtocol = de_push_sequence(attribute);
{
de_add_number(l2cpProtocol, DE_UUID, DE_SIZE_16, 0x0100);
}
de_pop_sequence(attribute, l2cpProtocol);
uint8_t* rfcomm = de_push_sequence(attribute);
{
de_add_number(rfcomm, DE_UUID, DE_SIZE_16, 0x0003); // rfcomm_service
de_add_number(rfcomm, DE_UINT, DE_SIZE_8, service_id); // rfcomm channel
}
de_pop_sequence(attribute, rfcomm);
}
de_pop_sequence(service, attribute);
// 0x0005 "Public Browse Group"
de_add_number(service, DE_UINT, DE_SIZE_16, SDP_BrowseGroupList); // public browse group
attribute = de_push_sequence(service);
{
de_add_number(attribute, DE_UUID, DE_SIZE_16, 0x1002 );
}
de_pop_sequence(service, attribute);
// 0x0006
de_add_number(service, DE_UINT, DE_SIZE_16, SDP_LanguageBaseAttributeIDList);
attribute = de_push_sequence(service);
{
de_add_number(attribute, DE_UINT, DE_SIZE_16, 0x656e);
de_add_number(attribute, DE_UINT, DE_SIZE_16, 0x006a);
de_add_number(attribute, DE_UINT, DE_SIZE_16, 0x0100);
}
de_pop_sequence(service, attribute);
// 0x0009 "Bluetooth Profile Descriptor List"
de_add_number(service, DE_UINT, DE_SIZE_16, SDP_BluetoothProfileDescriptorList);
attribute = de_push_sequence(service);
{
uint8_t *sppProfile = de_push_sequence(attribute);
{
de_add_number(sppProfile, DE_UUID, DE_SIZE_16, 0x1101);
de_add_number(sppProfile, DE_UINT, DE_SIZE_16, 0x0100);
}
de_pop_sequence(attribute, sppProfile);
}
de_pop_sequence(service, attribute);
// 0x0100 "ServiceName"
de_add_number(service, DE_UINT, DE_SIZE_16, 0x0100);
de_add_data(service, DE_STRING, strlen(name), (uint8_t *) name);
}